DE954626C - Gas discharge tubes with cold cathode - Google Patents

Description

Cold Cathode Gas Discharge Tube The invention relates to a cold cathode gas discharge tube in which the current flows between the main cathode and the anode by applying voltages to one or more auxiliary electrodes is controlled. It is known that these tubes have an anode, a cathode and a Have control grid that need not be a grid in the mechanical sense, and that Ionization in the grid-cathode space leads to ionization in the anode-cathode space. The upswing, the circuit arrangements with such tubes, z. B. for counting and for switching, however, makes it necessary to change the characteristics and in particular the constancy of the characteristic curves during the service life of a tube as well as the uniformity to improve the characteristics of the tubes with each other.

The present invention aims to provide a gas discharge tube with cold To create cathode with characteristics improved in the above sense.

The invention is based on a gas discharge tube with a cold cathode and an auxiliary discharge shielded from the main discharge, which tube is a Contains main anode, main cathode, control electrode and ignition electrode, between which two last electrodes an auxiliary discharge is maintained can be in a space completely separated from the main anode-main cathode discharge path is separated. According to the invention, the main cathode forms the screen, and the auxiliary discharge extends through a Opening in the main cathode and can be increased by increasing the voltage difference between Control electrode and transition cathode along the transition cathode to the main discharge path are spread so that the main discharge ignites.

In a certain embodiment of the invention in which this type is applied, the main cathode is cylindrical and with its axis against the The anode is attached directionally, and it is through at the end facing the anode a circular disc closed with an opening.

According to another embodiment, there is similar to the last-described embodiment as a screen acting cathode of three planes Surfaces, namely one of the anode facing, provided with an opening end face as well as two side surfaces which extend backwards in such a way that they are the area of the Include discharge between the ignition cathode and the grid. With this type of construction the cathode is made of thin sheet metal or fine metal mesh be.

Such a gas discharge tube is preferred over the known types a lower and more uniform "grid" ignition voltage, because the latter is practical corresponds to the grid operating voltage, and as is known, the operating voltage is a Discharge between two electrodes in a gas under low pressure during the The service life of a tube is relatively constant and even with several tubes of the same Kind of less different.

The reduction in the grid ignition voltage also requires an increase the ratio between the output voltage difference of the tube, d. H. the difference between the maximum anode voltage and the anode operating voltage, at the without Grid voltage still no ignition occurs, and the grid ignition voltage.

In addition, the tube's ionization time has always decreased compared to the Tubes of a known type, since the ignition of the tube is the extension of an already existing one Glimmlichtentladüng brings with it, which in itself takes place faster than the introduction a new discharge.

The invention is illustrated below with reference to the drawing, for example explained in more detail in the two embodiments of a gas discharge tube according to the Invention are shown.

Fig. I is a schematic cross section through a simple embodiment a gas discharge tube with a cylindrical main cathode, which also acts as a screen; Fig. 2 shows a cross section through a gas discharge tube, the cathode also acts as a screen and has three flat surfaces, and Fig. 3 is a perspective view Representation of the auxiliary electrodes of the tube shown in Fig. 2, with the main cathode viewed from the rear.

The tube of Fig. I has a rod-shaped anode i and a cylindrical one Main cathode 2 with a diameter of 1.5 cm and a length of 1.5 cm, the are housed in a gas-filled envelope 3. The main cathode 2 is with the Axis facing the anode i, from which it has a distance of 1.8 cm. On which the The anode facing end is the cathode by a circular, with one in the On the axis of the electrode, there is an opening 5 provided with a 2 mm diameter disc 4. locked. A transition cathode 6 is arranged in the axis of the cathode 2 and extends through the opening 5 from the outside (main discharge path) inside (auxiliary discharge balin). Outside the main cathode 2 is the transition cathode 6 bent at right angles to the cathode axis and then, by means of a seal in the glass envelope 3 through the tube wall to the outside. In the axis of the cathode is at a distance of 2 mm from the inner end of the junction cathode 6 and an ignition cathode at a distance of 7 mm from the opening 5 in the main cathode 7 attached. A control pin 8 ("control grid") perpendicular to the axis of the Cathode, has a distance of 2 mm from the ends of the junction cathode at the end 6 and the ignition cathode 7 and is arranged approximately halfway between them. All electrodes are made of molybdenum, and the gas filling that. 99% made of neon and consists of 100% argon, has a pressure of 20 mm of oxy-silver acid. The main cathode 2 is carried by a rigid wire 9 passed through the sheath 3 of the tube, which forms the electrical connection for the cathode.

A well-known atomization process is used in the manufacture of the tube carried out, in which a strong discharge current alternating between the different Electrodes is guided so that part of the surface of the electrodes is sputtered and settles on the glass envelope. This is used to clean the surface of the Electrodes and for. Purification of the gas. The layer deposited on the glass envelope also serves to hold impurities in the pores of the glass envelope.

The anode of the tube is positive through a resistor to a source Voltage is connected, and the main cathode and the junction cathode become each other connected and grounded. The ignition cathode is connected to a source via a resistor negative voltage of approximately 100 V and the control grid via a resistor connected to a grid control voltage source.

When the tube is in operation, the auxiliary discharge is ignited in such a way that that the grid voltage is increased to approximately 5o V positive towards the cathode, whereupon ionization takes place between the grid and the ignition cathode and an auxiliary discharge passes between these two electrodes. This auxiliary discharge is through the Resistance that the ignition cathode with the source of negative voltage connects, limited to a few microamps of current and has no influence on the Conditions in the main discharge space between the anode and the cathode due to of the intermediate screen formed by the main cathode. The auxiliary discharge however, has a controlling influence on the conditions in that of the main cathode enclosed space from where in particular the value of the breakdown voltage between the control grid and the junction cathode due to the proximity of the auxiliary discharge the burning voltage between these two electrodes is reduced. Will thus Grid voltage from the mentioned initial value of approximately 5o V to a value of approximately 9o V, i.e. H. the ignition voltage between the grid and the junction cathode, if the auxiliary discharge increases, which is exclusive up to this moment between the grid and the ignition cathode, over the junction cathode expand and in this way pass through the opening in the main cathode extend into the area of the main discharge path. When the conductive edge of the auxiliary discharge moving through the junction cathode through the opening in the main cathode passes through, the auxiliary discharge is influenced by the anode-cathode field exposed so that ionization occurs between the anode and the junction cathode, which immediately brings about icrization between the anode and the main cathode will.

It can be seen that the described sequence of operations of the tube according to the invention by the presence of the screen as described above Example of the main cathode. itself, creating the area of the main discharge and that Geb '= _ et the auxiliary discharge are separated from each other, as well as by the arrangement a junction electrode is made possible, which extends from the auxiliary discharge region extends into the main discharge area. Without the separation between the two Areas would be the auxiliary discharge, which the breakdown voltage between the Grid and the junction cathode also reduces the breakdown voltage between the anode and the junction cathode and in this way the main discharge initiate.

It can also be seen that the described mode of operation of The tube does not depend on the separation between the main cathode and the junction cathode is, since these two electrodes in the described circuit arrangement with each other are connected. However, if a number of these tubes are to be used together, so there will be circuit arrangements in which the creation of different Voltages across these two electrodes offers practical advantages. The ignition of the described tube is of the manufacture of a certain voltage difference between the grid and the junction cathode, regardless of the voltage between the Grid and the junction cathode, and it is therefore possible to put the tube on -to ignite a negative pulse at the junction cathode. being the tensions of the grid and the main cathode remain constant.

In addition, the ignition cathode can be used as a blocking electrode, since, unless the appropriate negative voltage is applied to the ignition cathode, the tube is not affected by the usual operating voltage difference between the grid and the junction cathode can be ignited. This detail enables the application of tubes according to the invention in electronic counting and switching devices.

The other, shown in Fig. 2 and 3.-embodiment of the tube, in which the same-i-lz electrodes with the same reference numerals as in Fig. i has a base made of pressed glass through which eight lead wires are passed through. Five of the lead wires are shown in the drawing and denoted by i i to 15 and occur in the section shown in FIG. These lead wires are outside as contact pins for the tube and inside as Holder for the electrode system wiri_sant. the lamp base io is due to Gi_asstumpschwci ° n a cylindrical sheath 3 connected, and with the insertion wire i i is through Welding a st =; li-shaped anode i connected, which is parallel to the axis of the Sheath 3 in arnäbernd half the length of the same extends and on it in such a way: under is bent at right angles to the center of a circular opening 5 in the face of the main cathode 2 faces. The main cathode 2 is rigid Wires 9 and this = -in turn carried by the lead wires. In this way is as shown in Fig. -2. one of these holding wires with the lead-in wire 1.4 connected. The main catho <@ 2 is also effective as the shield of the tube and 1 - a @ two side surfaces that extend backwards opposite the anode i and that Enclose the area of the auxiliary electrodes now to be described. These electrodes belongs to an ignition cathode 7, which is carried by d-trz insertion wire 15 and parallel to the axis of the envelope to the same height as the anode i rises, at what level it is bent at a right angle, with the end in shape a loop 6 which is arranged opposite the opening 5. Of the Insertion wire 13 carries a cathode 6 which is approximately in the axis the I-ulle 3 lies and rises up to the level of the opening 5, where it is below right Angle is bent and both through the opening 5 and through the loop 16 of the ignition cathode 7 extends through it. A control grid arranged behind the cathode 2 8 is carried in front of one of the insertion wires, not shown in FIG. 2, and extends, as is particularly evident from FIG. 3, up to the vicinity the loop 16 of the ignition cathode 7.

In this embodiment the cathode is: 2 10 mm wide and its sides protrude back 10 mm; the entire electrode is 50 mm high. In the end face, in the center line of this surface, a circular opening 5 with a diameter of 2 mm is provided at a distance of 20 mm from the upper edge and 30 mm from the lower edge. The ignition cathode 7 is a molybdenum rod with a diameter of 0.5 mm, which protrudes from the base, bends at a distance of approximately 10 mm from the rear of the cathode towards this rear side until it is approximately 5 mm away from it, and is then designed in the form of a loop 16 with a diameter of 2 mm, measured from the center of the wire, ie that the ring formed has a clear diameter of 1.5 mm. The transition cathode 6 is a molybdenum rod with a diameter of 0.5 mm. The clearance between the junction cathode 6 and the front surface of the cathode 2 is small, but not critical. The grid 8 is a molybdenum rod with a diameter of 0.5 mm, which rises at a distance of 5 mm from the end face and the sides of the cathode. A distance of 2 mm remains between the ends of the grid 6 and the circumference of the loop 16. The main anode i is also a molybdenum rod with a diameter of 0.5 mm, and the spacing of the. The end face of the cathode 2 from the summit of the anode i is approximately 18 mm. The envelope 3 is filled with a gas filling of 99 % neon and 10/9 argon under a pressure of 20 mm of mercury.

The cathode 2 can be made of thin molybdenum sheet or of fine molybdenum fabric be made. The circuit for the embodiments of Figs. 2 and 3 is the same as that described for the embodiment of Fig. i; also is the kind of operation the same.

Claims (5)

PATENT CLAIMS: i. Gas discharge tube with a cold cathode and one auxiliary discharge shielded from the main discharge, which tube is a main anode, a main cathode, a control electrode and an ignition electrode contains between which two last electrodes an auxiliary discharge can be maintained in a space that is completely separated from the main anode-main cathode discharge path is characterized in that the main cathode forms the screen and the auxiliary discharge extends through an opening in the main cathode during a transition period and by increasing the voltage difference between the control electrode and the transition cathode can be spread along the junction cathode to the main discharge path, so that the main discharge ignites. 2. Gas discharge tube with cold cathode after Claim i, wherein the main cathode is cylindrical and with its axis the anode is attached facing, at the end opposite the anode by a circular Disc is closed with an opening. 3. Gas discharge tube with cold cathode according to claim i, wherein the main cathode consists of three flat surfaces, namely an end face opposite the anode and provided with an opening, as well as two rearwardly running side surfaces to enclose the area of the discharge between the ignition cathode and the control electrode. q .. Gas discharge tube with cold Cathode according to Claim 3, in which the main cathode is made of metal mesh. 5. Gas discharge tube with cold cathode according to one of the preceding claims, in which the ignition cathode is designed at the end in the form of a loop through which the transition cathode extends. Contemplated publications: USA. Patents No. 2560346, 2577809, 2331398;. German patent specification No. 67o 931.